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== '''ATP Synthase''' == | == '''ATP Synthase''' == | ||
<StructureSection load='5lqz' size='350' side='right' caption='ATP Synthase (PDB entry [[5lqz]])' scene=''> | <StructureSection load='5lqz' size='350' side='right' caption='ATP Synthase (PDB entry [[5lqz]])' scene='78/781973/Start/1'> | ||
ATP synthase is shown here to the right ==> | |||
It is depicted in 3D with each protein shown in a different colour. | |||
ATP synthase | Tools for exploring ATP synthase in 3D | ||
- left mouse button to rotate the protein model. | - left mouse button to rotate the protein model. | ||
| Line 20: | Line 15: | ||
- right mouse button for more options and information (control-click on a Mac). | - right mouse button for more options and information (control-click on a Mac). | ||
- green text - click to load a new 3D scene | |||
'''Have a go yourself now ==>''' | |||
'''Exploring the ATP synthase molecule''' | '''Exploring the ATP synthase molecule''' | ||
ATP synthase is built up of different groups of proteins: the F0, the F1, the stator | ATP synthase is a cellular molecular motor found in the mitochondrial membrane of humans, and also in other organisms. It has a role in the generation of ATP, the cells energy currency. This large molecule is built up of a number of different groups of proteins: the F0, the F1, and the stator - each group has an important role to play. | ||
The <scene name='78/781973/Alpha-beta/1'>F1 motor</scene> contains alpha (shown in light blue) and beta (shown in dark blue) | |||
'''The F1 and Axle''' | |||
The <scene name='78/781973/Alpha-beta/1'>F1 motor head</scene> contains an α (alpha) chain (shown in light blue) and a β (beta) chain (shown in dark blue). The <scene name='78/781973/Axel/1'>axle</scene>, rotates (like the axle on a car), and is composed mainly of the <scene name='78/781973/Gamma/1'> γ (gamma) </scene> protein chain. The axle rotates with three 120° steps, putting the β chains into three different conformations, allowing the ADP and phosphate to bind, the high energy bond to form and the release of ATP. | |||
---- | |||
'''Q1: Describe how the protein chains are arranged to comprise the F1 region?''' | |||
---- | ---- | ||
''' | '''Q2: What is the role of the axle, explain how it acts on the β subunits?''' | ||
---- | ---- | ||
''' | |||
'''ADP and ATP are bound in the nucleotide binding sites''' | |||
The F1 shown here has both adenosine diphosphate (ADP) and adenosine triphosphate (ATP) bound in the <scene name='78/781973/Atpandadp/1'>nucleotide binding sites</scene>. See if you can zoom in on the ATP identify the phosphate atoms (orange), sugar moiety and the base moiety. ==> | |||
The three nucleotide binding sites, primarily located in the β subunits, carry out active ATP synthesis. The sites primarily located in the three α subunits are non-catalytic and exchange bound nucleotide very slowly. They are thought to be a carry over from evolution, and now play a more regulatory role. | |||
---- | ---- | ||
''' | '''Q3: How many phosphates atoms (orange) does ATP have, and how does this differ to ADP?''' | ||
---- | ---- | ||
''' | '''Q4: Between which atoms is the high energy bond formed, and in which location in the ATP synthase does the catalysis occur (which chain)?''' | ||
---- | ---- | ||
<scene name='78/781973/F0/1'>The F0</scene> is a circular rotor that is formed of | '''The F0 region''' | ||
<scene name='78/781973/F0/1'>The F0</scene> is a circular rotor that is formed of transmembrane α-helices located in the inner mitochondrial membrane. The positively charged hydrogen ions (protons) travel around the circular F0 motor, and turning the F0 rotor in the process, much like a waterwheel. Firstly, the hydrogen ion binds a negatively charged <scene name='78/781973/Aspgluchain/1'>aspartic acid or glutamic acid</scene> residue (amino acid) within the transmembrane α-helices of the F0 motor. This action then allows the F0 to turn, as it can only turn in the hydrophobic membrane when a hydrogen ion is bound to these amino acids, as it neutralises the amino acids negative charge. Secondly, after a full rotation, the hydrogen is removed from the rotor by an <scene name='78/781973/Arg/1'>arginine</scene> amino acid, into a charged pocket, and then is passed to the opposite side of the membrane. | |||
---- | ---- | ||
''' | '''Q5: What is the location and role of the F0 region. How many Transmembrane α-helices are there?''' | ||
---- | ---- | ||
''' | '''Q6: Name two key amino acids, one acidic and one basic, that influence the hydrogen ions's path within the the F0. Which one acts like a broom sweeping the protons off the rotor?''' | ||
---- | ---- | ||
'''Summary''' | |||
The synthesis of ATP, the cells energy currency, involves a number of steps performed by a tiny molecular motor found in the mitochondrial membrane, called ATP synthase. | |||
'''Key Terms''' | '''Key Terms''' | ||
ATP = Adenosine triphosphate (nucleotide) | |||
ADP = Adenosine diphosphate (nucleotide) | |||
Aspartic acid = An acidic amino acid (negatively charged) | |||
Glutamic acid = An acidic amino acid (negatively charged) | |||
Arginine = A basic amino acid (positively charged) | |||
Transmembrane α-helices = Membrane-spanning α-helices | |||
ATP synthase = A molecular motor that generates ATP | |||
Hydrogen ion = A hydrogen atom that has lost (or gained) an electron. A positively charged hydrogen ion is also referred to as a proton | |||
Moiety = A "part" or "functional group" of a molecule | |||
You were viewing the molecular model using the Jmol viewer within [http://proteopedia.org/wiki/index.php/Main_Page Proteopedia]. | |||
</StructureSection> | </StructureSection> | ||
Latest revision as of 21:30, 24 March 2018
ATP SynthaseATP Synthase
ATP synthase is shown here to the right ==> It is depicted in 3D with each protein shown in a different colour.
Tools for exploring ATP synthase in 3D - left mouse button to rotate the protein model. - middle mouse button or scroll wheel to zoom (option-click on a Mac) - right mouse button for more options and information (control-click on a Mac). - green text - click to load a new 3D scene
Have a go yourself now ==>
Exploring the ATP synthase molecule ATP synthase is a cellular molecular motor found in the mitochondrial membrane of humans, and also in other organisms. It has a role in the generation of ATP, the cells energy currency. This large molecule is built up of a number of different groups of proteins: the F0, the F1, and the stator - each group has an important role to play.
The F1 and Axle The contains an α (alpha) chain (shown in light blue) and a β (beta) chain (shown in dark blue). The , rotates (like the axle on a car), and is composed mainly of the protein chain. The axle rotates with three 120° steps, putting the β chains into three different conformations, allowing the ADP and phosphate to bind, the high energy bond to form and the release of ATP. Q1: Describe how the protein chains are arranged to comprise the F1 region? Q2: What is the role of the axle, explain how it acts on the β subunits?
ADP and ATP are bound in the nucleotide binding sites The F1 shown here has both adenosine diphosphate (ADP) and adenosine triphosphate (ATP) bound in the . See if you can zoom in on the ATP identify the phosphate atoms (orange), sugar moiety and the base moiety. ==> The three nucleotide binding sites, primarily located in the β subunits, carry out active ATP synthesis. The sites primarily located in the three α subunits are non-catalytic and exchange bound nucleotide very slowly. They are thought to be a carry over from evolution, and now play a more regulatory role. Q3: How many phosphates atoms (orange) does ATP have, and how does this differ to ADP? Q4: Between which atoms is the high energy bond formed, and in which location in the ATP synthase does the catalysis occur (which chain)?
The F0 region is a circular rotor that is formed of transmembrane α-helices located in the inner mitochondrial membrane. The positively charged hydrogen ions (protons) travel around the circular F0 motor, and turning the F0 rotor in the process, much like a waterwheel. Firstly, the hydrogen ion binds a negatively charged residue (amino acid) within the transmembrane α-helices of the F0 motor. This action then allows the F0 to turn, as it can only turn in the hydrophobic membrane when a hydrogen ion is bound to these amino acids, as it neutralises the amino acids negative charge. Secondly, after a full rotation, the hydrogen is removed from the rotor by an amino acid, into a charged pocket, and then is passed to the opposite side of the membrane. Q5: What is the location and role of the F0 region. How many Transmembrane α-helices are there? Q6: Name two key amino acids, one acidic and one basic, that influence the hydrogen ions's path within the the F0. Which one acts like a broom sweeping the protons off the rotor?
Summary The synthesis of ATP, the cells energy currency, involves a number of steps performed by a tiny molecular motor found in the mitochondrial membrane, called ATP synthase.
Key Terms ATP = Adenosine triphosphate (nucleotide) ADP = Adenosine diphosphate (nucleotide) Aspartic acid = An acidic amino acid (negatively charged) Glutamic acid = An acidic amino acid (negatively charged) Arginine = A basic amino acid (positively charged) Transmembrane α-helices = Membrane-spanning α-helices ATP synthase = A molecular motor that generates ATP Hydrogen ion = A hydrogen atom that has lost (or gained) an electron. A positively charged hydrogen ion is also referred to as a proton Moiety = A "part" or "functional group" of a molecule
You were viewing the molecular model using the Jmol viewer within Proteopedia.
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